Open Access Article
This Open Access Article is licensed under a Creative Commons Attribution-Non Commercial 3.0 Unported Licence

Aldoximes enable proton-relayed NMR hyperpolarisation

Naomi E. Leydman and Philip L. Norcott *
Research School of Chemistry, Australian National University, 2601 Canberra, ACT, Australia. E-mail: philip.norcott@anu.edu.au

Received 30th June 2024 , Accepted 12th August 2024

First published on 12th August 2024


Abstract

NMR signals can be greatly enhanced, or hyperpolarised, by interactions with para-hydrogen. We demonstrate here that oximes can be reversibly hyperpolarised by coordination to an iridium complex, that oxime E/Z geometry is significant for activity, and that hyperpolarised oximes can subsequently transfer these enhanced signals through proton exchange.


A significant increase to the signal strength in nuclear magnetic resonance (NMR) spectroscopy and magnetic resonance imaging (MRI) can be achieved through hyperpolarisation.1 Typically, in an external magnetic field the bulk polarisation of a sample is very small, resulting in low sensitivity. This occurs from the small population difference between Zeeman-split states under thermal (Boltzmann) conditions. Perturbation of this thermal distribution by some means can lead to far larger population differences and accordingly a greater bulk magnetisation, that is, hyperpolarisation. This produces signals that may be orders of magnitude greater in intensity, a valuable feature currently being explored for clinical imaging and metabolic monitoring,2,3 or for the enhanced detection of biologically-relevant analytes,4,5 or for measurements at low magnetic field strengths.6,7

Several methods of hyperpolarisation exist, but a particularly accessible and affordable method involves para-hydrogen (p-H2), an isomer of hydrogen gas with a non-thermal nuclear spin order.8 Addition reactions with p-H2 can result in a hyperpolarised hydrogenation product,9 a process known as para-hydrogen induced polarisation (PHIP) which has been studied in the context of both homogeneous and heterogenous catalysis.10,11 An important non-hydrogenative variant of PHIP is signal amplification by reversible exchange (SABRE), where p-H2 and a target molecule can reversibly associate with a metal complex, allowing transfer of hyperpolarised magnetisation through the temporary J-coupling of the complex without chemically modifying the target.12,13 Normally, a requirement for this process is the target must have a suitable coordinating affinity to the metal centre, but it has also been shown that certain molecules capable of donating or accepting protons can deliver and/or accept SABRE hyperpolarisation via this exchange (a ‘relay’ step).14,15

Here, we demonstrate that aldoximes are amenable ligands for SABRE (Fig. 1), revealing the key properties that influence hyperpolarisation level, the active catalyst species, and the ability and utility of oximes to engage in SABRE-relay.


image file: d4cc03231d-f1.tif
Fig. 1 Transfer of hyperpolarised magnetisation from p-H2 to oximes via an iridium complex, followed by signal transfer via proton exchange.

Oximes are oxygenated imine analogues widely used in organic synthesis,16 coordination chemistry,17 and notably as antidotes against organophosphate poisioning.18 To begin our study, we sought to react the benzaldehyde oxime 1 (Fig. 2) with the commonly used SABRE pre-catalyst [IrCl(COD)(IMes)] (COD = 1,5-cis,cis-cyclooctadiene, IMes = 1,3-bis(2,4,6-trimethylphenyl)imidazol-2-ylidine). In conventional SABRE under H2 an Ir(III) dihydride species is formed and following COD hydrogenation three sites are available for coordination of a target molecule. For 1, we anticipated that the oxime geometry would dramatically affect the coordinating ability as E and Z forms would exhibit very different steric environments.


image file: d4cc03231d-f2.tif
Fig. 2 (a) Thermal and hyperpolarised single-scan 1H NMR spectra (60 MHz) of the geometric isomers of 1. [Oxime] = 30 mM and [IrCl(COD)(IMes)] = 10 mM in CD2Cl2 under 2 bar p-H2. Thermal spectra vertical scale expanded x8 for clarity. (b) Hyperpolarised 1H spectrum of Z-1 under analogous conditions at 400 MHz. (c) Optimised geometries and relative Gibbs free energies for complexes [IrX(H)2(IMes)(Z-1)2] where X = Cl or H2O; ωB97X-D/def2-SVP//ωB97X-D/def2-TZVPP.

The reaction of benzaldehyde dimethyl acetal with hydroxylamine hydrochloride gave two isomers of oxime 1 which could be readily separated chromatographically, but in our hands dissolution of either product in CDCl3 revealed equilibrium mixtures of E and Z oximes. Dissolution in d6-DMSO or CD2Cl2, however, prevented any equilibration in solution.

With E-1 and Z-1 in hand, we combined each oxime (30 mM) with [IrCl(COD)(IMes)] (10 mM) in CD2Cl2. The sample was shaken under p-H2 (2 bar) for 10 seconds at 65 G then immediately transferred to a 1.4 T (60 MHz) NMR spectrometer and acquisition of a single-scan 1H spectrum. As seen in Fig. 2a, Z-1 was significantly more effective than E-1, showing hyperpolarised oxime responses with signal enhancements of 113-fold over the normal spectrum for Z-1, compared to only 6-fold for E-1. The weaker hyperpolarisation for E-1 supports our steric argument, and is reminiscent of recent reports of the dependence on E and Z azobenzenes for SABRE activity, with a preference for the less sterically encumbered Z isomer.19

Interestingly, a hyperpolarised peak corresponding to H2O (1.5 ppm), presumably present in trace amounts in the solvent, could also be observed. We recognised that a response at this chemical shift may also correspond to hyperpolarised cyclooctane (a PHIP result rather than SABRE), but to refute this we found that repeated treatments with fresh p-H2 continued to give this hyperpolarised resonance even after the sample was left to react completely for several days under H2 while high-field NMR analysis revealed complete consumption of COD within minutes to an hour. A hyperpolarised o-H2 resonance (4.6 ppm) is also observed, indicating reversible addition and elimination of dihydrogen.

At a higher detection field (400 MHz), additional hyperpolarised responses corresponding to bound oxime ligands were also detected (Fig. 2b). These are consistent with a catalyst structure of the form [IrCl(H)2(IMes)(Z-1)2] which is supported by density functional theory (DFT) calculations (Fig. 2c, vide infra). A bound oxime ligand cis to the IMes ligand (Z-1eq) was enhanced by a similar amount to the free oxime ligand (around 50-fold at the N[double bond, length as m-dash]CH position), while those of the oxime trans to the IMes (Z-1ax) showed weaker but measurable hyperpolarisation (only 10-fold enhancement). This may be in part due to a slower ligand exchange at this position, which we have also observed through exchange spectroscopy (EXSY) measurements, and is supported by a brief examination of polarisation transfer at an increased temperature which increases enhancement (ESI, Section S1.4).

The notable exception to this trend was the OH responses of both bound ligands, which were more consistently hyperpolarised (each approximately 70-fold enhancement), which is a similar magnitude to the free oxime OH and H2O itself. The imidazole of the NHC only exhibited very weak hyperpolarisation. Details of enhancement values, assignments of this complex, and a screen of the polarisation transfer field can be found in Appendix S2 of the ESI.

In addition to the steric differences between E/Z isomers, oximes of different electronic properties were also investigated: a (p-OMe)-phenyl (2) and a (p-CF3)-phenyl (3) analogue to probe more electron-rich and electron-deficient oximes, respectively (Appendix S3 in the ESI). In both cases, the Z isomers were superior to the corresponding E isomers. The most notable electronic effect was the withdrawing CF3 functional group on 3 reduced the SABRE activity significantly, with Z-3 showing hyperpolarised hydrides but little else. However, the presence of a donating OMe functional group on 2 did not reveal a dramatic change compared to the unfunctionalised compound 1, with Z-2 displaying oxime resonances enhanced by only 28-fold. For analogues bearing multiple OMe groups, the increased size appeared to hinder any advantage that may have been gained from electronic effects.

To support the identity of the reactive species during these processes, we investigated the most effective of these analogues, Z-1, more closely. Thermally polarised spectra at 400 MHz reveal that only 2 equivalents of oxime coordinate to iridium (see Appendix S1, ESI). This is consistent with the observed inequivalent hydride resonances at −22.7 and −26.4 ppm, suggesting a non-symmetrical complex of the form [IrX(H)2(IMes)(Z-1ax)(Z-1eq)], where ax = axial, eq = equatorial (Fig. 2c), and X is a ligand we considered plausibly could be Cl, H2O, or a chelation mode. 2D EXSY revealed only the equatorially bound Z-1eq exchanges with free Z-1. Two sharp resonances indicating intramolecularly hydrogen-bonded OH groups each from Z-1ax and Z-1eq (11.0 and 11.2 ppm) also showed an exchange interaction with free H2O.

To differentiate between an active complex with a bound H2O or Cl in the X site, CD2Cl2 that had been dried over CaH2 followed by 4 Å MS was used to exclude all spurious water from the solvent. Even when this SABRE sample was doped with 2 eq. MeOH (with respect to Ir) an identical complex was revealed, with no discernible difference in the chemical shift of the hydrides, suggesting a bound H2O is less plausible. The reaction with p-H2, notably, now produced a strong hyperpolarised MeOH response with the methyl group enhanced by 173-fold over the thermal spectrum (see Appendix S3, ESI).

DFT calculations also suggest the more thermodynamically stable complex is [IrCl(H)2(IMes)(Z-1)2], rather than [Ir(H2O)(H)2(IMes)(Z-1)2]Cl, by 95.1 kJ mol−1 (Fig. 2c). We were unable to find any reasonable structures with bidentate oxime N,O-coordination. The lowest energy conformer of the preferred complex displayed two intramolecular hydrogen-bonding interactions with the adjacent Cl, consistent with our previously discussed spectroscopic observations. Structures were optimised with a continuum solvation model (SMD)20 in dichloromethane using the ωB97X-D functional21 and def2-SVP basis set.22 Subsequent single point energies were calculated using the def2-TZVPP basis set.

These studies therefore suggest that the observed hyperpolarisation of H2O or MeOH is through a SABRE-relay process (via proton exchange), rather than directly through an Ir-bound H2O or MeOH. We also found that n-butanol participated in a similar fashion. There have already been fairly comprehensive studies of different substrates containing exchangeable protons that participate in SABRE-relay where primary amines are used to coordinate to iridium,14 and from our results we would expect a similar scope to be possible here.

However, the consistent OH hyperpolarisation levels between bound and free oxime ligands and H2O identified earlier in this work suggest the SABRE relay mechanism may also exhibit some distinguishing features. Specifically, it is possible proton exchange to water or alcohols may proceed directly from the Ir catalyst, without oxime dissociation being strictly necessary. In particular, the exchange spectroscopy measurements available in Appendix S1 of the ESI reveal proton exchange between the axially-bound OH resonance and H2O, despite slow dissociation of this ligand from the metal centre. The ability to deliver proton-relayed hyperpolarisation in part disconnected from the rate of organic ligand dissociation may be a promising alternative strategy to conventional SABRE-relay in future work.

It is evident that the role of oximes in these examples is as the ‘mediator’ in the SABRE-relay process: a molecule able to coordinate Ir to acquire SABRE-derived magnetisation then to discharge it via proton-transfer to a ‘target’ (alcohols in this case), according to the terminology we show in the general sequence in Fig. 3a. However, we also wanted to see if oximes could act as ‘targets’ (poorly binding to Ir, but receiving hyperpolarised magnetisation via proton transfer). This would allow signal enhancement of even the more sterically hindered E-isomers we investigated at the outset of this work.


image file: d4cc03231d-f3.tif
Fig. 3 (a) Typical roles of mediator and target in SABRE-relay, with (b) geometric isomers of oximes playing different roles. (c) Hyperpolarised 1H NMR spectra of a mixture of E and Z isomers of oxime 1.

As such, we prepared a sample of 1 (30 mM) consisting of an equilibrium mixture of E[thin space (1/6-em)]:[thin space (1/6-em)]Z isomers present in a 14[thin space (1/6-em)]:[thin space (1/6-em)]1 ratio and [IrCl(COD)(IMes)] (10 mM) in CD2Cl2 for SABRE as before. Whereas pure E-1 originally performed poorly, the 14[thin space (1/6-em)]:[thin space (1/6-em)]1 E[thin space (1/6-em)]:[thin space (1/6-em)]Z mixture gave much improved hyperpolarised signal responses (Fig. 3c). We propose that steric constraints force only the Z isomer to act as SABRE-relay mediator while proton exchange allows the E isomer to act as the target. Indeed, from this mixture we could not detect any hyperpolarised free Z-1 as this is presumably iridium-bound (noting the identical resonances in the hydride region in Fig. 3c), and we observed only hyperpolarised free E-1. We suggest that this is a crucial consideration given our observations of the propensity of oximes to isomerise even under weakly acidic conditions, as future applications in this area may likely involve (intentionally or unintentionally) thermodynamic mixtures of E and Z compounds. Further DFT modelling revealed that for competitive binding in a mixture of E and Z oximes, coordination by Z-1 was thermodynamically preferred, but that complexes with mixed ligand speciation such as [IrCl(H)2(IMes)(Z-1)(E-1)] (refer to Appendix S4, ESI) cannot be discounted as also contributing to this effect.

In conclusion, we have shown that aldoximes are amenable to SABRE using the most common iridium catalyst, with the Z-configured oxime playing the primary role of coordination. The pendant OH on these molecules provides a route for transfer of hyperpolarised magnetisation both to and from oximes via proton exchange. Investigations into related derivatives are ongoing in our laboratory, and will be reported in due course.

P. L. N. gratefully acknowledges a Discovery Early Career Researcher Award (DECRA) from the Australian Research Council (DE210100065). This work was undertaken with the assistance of resources and services from the National Computational Infrastructure (NCI), which is supported by the Australian Government. N. E. L. conducted synthetic and analytical experiments and reviewed the manuscript. P. L. N. conceived the project, wrote the initial draft, and performed synthetic, analytical and computational experiments.

Data availability

Raw NMR data files supporting this work are openly available in the Australian National University Data Commons located at https://datacommons.anu.edu.au (10.25911/5c3t-7137).

Conflicts of interest

There are no conflicts to declare.

Notes and references

  1. J. Eills, D. Budker, S. Cavagnero, E. Y. Chekmenev, S. J. Elliott, S. Jannin, A. Lesage, J. Matysik, T. Meersmann, T. Prisner, J. A. Reimer, H. Yang and I. V. Koptyug, Chem. Rev., 2023, 123, 1417–1551 CrossRef CAS PubMed .
  2. H. de Maissin, P. R. Groß, O. Mohiuddin, M. Weigt, L. Nagel, M. Herzog, Z. Wang, R. Willing, W. Reichardt, M. Pichotka, L. Heß, T. Reinheckel, H. J. Jessen, R. Zeiser, M. Bock, D. von Elverfeldt, M. Zaitsev, S. Korchak, S. Glöggler, J.-B. Hövener, E. Y. Chekmenev, F. Schilling, S. Knecht and A. B. Schmidt, Angew. Chem., Int. Ed., 2023, 62, e202306654 CrossRef CAS PubMed .
  3. K. MacCulloch, A. Browning, D. O. Guarin Bedoya, S. J. McBride, M. B. Abdulmojeed, C. Dedesma, B. M. Goodson, M. S. Rosen, E. Y. Chekmenev, Y.-F. Yen, P. TomHon and T. Theis, J. Magn. Reson. Open, 2023, 16–17, 100129 CrossRef PubMed .
  4. N. Reimets, K. Ausmees, S. Vija, A. Trummal, M. Uudsemaa and I. Reile, Analyst, 2023, 148, 5407–5415 RSC .
  5. A. Alshehri, B. J. Tickner, W. Iali and S. B. Duckett, Chem. Sci., 2023, 14, 9843–9853 RSC .
  6. R. Kircher, J. Xu and D. A. Barskiy, J. Am. Chem. Soc., 2024, 146, 514–520 CrossRef CAS PubMed .
  7. N. Iqbal, D. O. Brittin, P. J. Daluwathumullagamage, M. S. Alam, I. M. Senanayake, A. T. Gafar, Z. Siraj, A. Petrilla, M. Pugh, B. Tonazzi, S. Ragunathan, M. E. Poorman, L. Sacolick, T. Theis, M. S. Rosen, E. Y. Chekmenev and B. M. Goodson, Anal. Chem., 2024, 96, 10348–10355 CrossRef CAS PubMed .
  8. G. Buntkowsky, F. Theiss, J. Lins, Y. A. Miloslavina, L. Wienands, A. Kiryutin and A. Yurkovskaya, RSC Adv., 2022, 12, 12477–12506 RSC .
  9. C. R. Bowers and D. P. Weitekamp, J. Am. Chem. Soc., 1987, 109, 5541–5542 CrossRef CAS .
  10. E. V. Pokochueva, D. B. Burueva, O. G. Salnikov and I. V. Koptyug, ChemPhysChem, 2021, 22, 1421–1440 CrossRef CAS PubMed .
  11. B. J. Tickner and V. V. Zhivonitko, Chem. Sci., 2022, 13, 4670–4696 RSC .
  12. R. W. Adams, J. A. Aguilar, K. D. Atkinson, M. J. Cowley, P. I. P. Elliott, S. B. Duckett, G. G. R. Green, I. G. Khazal, J. López-Serrano and D. C. Williamson, Science, 2009, 323, 1708–1711 CrossRef CAS PubMed .
  13. P. J. Rayner and S. B. Duckett, Angew. Chem., Int. Ed., 2018, 57, 6742–6753 CrossRef CAS PubMed .
  14. W. Iali, P. J. Rayner and S. B. Duckett, Sci. Adv., 2018, 4, eaao6250 CrossRef PubMed .
  15. P. J. Rayner, B. J. Tickner, W. Iali, M. Fekete, A. D. Robinson and S. B. Duckett, Chem. Sci., 2019, 10, 7709–7717 RSC .
  16. D. K. Kölmel and E. T. Kool, Chem. Rev., 2017, 117, 10358–10376 CrossRef PubMed .
  17. V. Y. Kukushkin and A. J. L. Pombeiro, Coord. Chem. Rev., 1999, 181, 147–175 CrossRef CAS .
  18. G. Mercey, T. Verdelet, J. Renou, M. Kliachyna, R. Baati, F. Nachon, L. Jean and P.-Y. Renard, Acc. Chem. Res., 2012, 45, 756 CrossRef CAS PubMed .
  19. A. S. Kiryutin, V. P. Kozinenko and A. V. Yurkovskaya, ChemPhotoChem, 2024, 8, e202300151 CrossRef CAS .
  20. A. V. Marenich, C. J. Cramer and D. G. Truhlar, J. Phys. Chem. B, 2009, 113, 6378–6396 CrossRef CAS PubMed .
  21. J.-D. Chai and M. Head-Gordon, Phys. Chem. Chem. Phys., 2008, 10, 6615–6620 RSC .
  22. F. Weigend and R. Ahlrichs, Phys. Chem. Chem. Phys., 2005, 7, 3297–3305 RSC .

Footnote

Electronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d4cc03231d

This journal is © The Royal Society of Chemistry 2024